Photosystem II regulation of macromolecule synthesis in the blue-green alga Aphanocapsa 6714.

Polymers synthesized by heterotrophically growing (glucose as carbon source) cultures of Aphanocapsa 6714 were compared with polymers synthesized in photosynthetically grown cultures. Loss of photosystem II by dark incubation, or inhibition of light-grown cells with the photosystem II-specific inhibitor dichlorophenylmethylurea, caused an 80 to 90% reduction in the rate of lipid and total ribonucleic acid synthesis, and more than a 90% reduction in the rate of protein synthesis. In contrast, glycogen synthesis was reduced only about 50% in dark cells and less than 30% in dichlorphenylmethylurea-inhibited cells. After longer heterotrophic growth, glycogen became the major component, whereas in photosynthetically grown cultures protein was the major constituent. 14C (from 14CO2 and/or [14C]glucose) assimilated into protein by heterotrophically grown cells was found in amino acids in nearly the same proportions as in photosynthetically grown cells. Thus, routes of biosynthesis available to autotropic cells were also available to heterotrophic cultures, but the supply of carbon precursors to those pathways was greatly reduced. The limited biosynthesis in heterotrophic cells was not due to a limitation for cellular energy. The adenylates were maintained at nearly the same concentrations (and hence the energy charge also) as in photosynthetic cells. The concentration of reduced nicotinamide adenine dinucleotide phosphate was higher in heterotrophic (dark) cells than in photosynthetic cells. From rates of CO2 fixation and/or glycogen biosynthesis it was determined that stationary-phase cells expended approximately 835, 165, and less than 42 nmol of adenosine 5'-triphosphate per mg (dry weight) of algae per 30 min during photosynthetic, photoheterotrophic, and chemoheterotrophic metabolism, respectively. Analysis of the soluble metabolite pools in dark heterotrophic cultures by double-labeling experiments revealed rapid equilibration of 14C through the monophosphate pools, but much slower movement of label into the diphosphate pools of fructose-1,6-diphosphate and sedoheptulose-1,7-diphosphate. Carbon did flow into 3-phosphoglycerate in the dark; however, the initial rate was low and the concentration of this metabolite soon fell to an undetectable level. In photosynthetic cells, 14C quickly equilibrated throughout all the intermediates of the reductive pentose cycle, in particular, into 3-phosphoglycerate. Analysis of glucose-6-phosphate dehydrogenase in cell extracts showed that the enzyme was very sensitive to product inhibition by reduced nicotinamide adenine dinucleotide.     

Inhibition of ribulose 1,5-diphosphate carboxylase by 6-phosphogluconate

6-Phosphogluconate is a much more effective inhibitor of the photosynthetic carboxylation enzyme, ribulose-1, 5-diphosphate carboxylase, than other sugar phosphates and sugar acids of the reductive and oxidative pentose phosphate cycles. The inhibition appears to be noncompetitive with ribulose 1,5-diphosphate. Since 6-phosphogluconate is unique to the oxidative cycle and inhibits at concentrations comparable to those found in vivo, it is proposed that its inhibition of the carboxylase may be a regulatory factor. If so, it would operate during darkness as a different control factor from those factors postulated to activate the carboxylase during photosynthesis.     

Effects of Sulfite on Metabolism in Isolated Mesophyll Cells from Papaver somniferum

Exposure (30 minutes) of leaf-free mesophyll cells from the C-3 plant, Papaver somniferum, to concentrations of sulfite (SO₂ + HSO₃⁻ + SO₃⁻) up to 20 millimolar stimulated the rate of CO₂ incorporation as much as 30%. The sulfite rapidly affects the metabolism of newly incorporated CO₂. Ammonia incorporation into glutamine and subsequent transamination reactions were stimulated during the short term exposure periods while glycolate metabolism apparently was inhibited by bisulfite at two points in the pathway. The results further indicate that glycolate is the major precursor of glycine in these cells. Prolonged periods of exposure (24 hours) to sulfite had somewhat different effects on carbon metabolism: the high concentrations (10 to 20 millimolar) severely inhibited all aspects of cellular metabolism while lower concentrations (1 millimolar) appeared to inhibit ammonia incorporation but stimulated synthesis of sucrose and starch.     

Light-Dark Regulation of Starch Metabolism in Chloroplasts: II. Effect of Chloroplastic Metabolite Levels on the Formation of ADP-Glucose by Chloroplast Extracts

The rate of ADP-glucose formation from [¹⁴C]glucose 6-phosphate and ATP by the soluble fraction of lysed chloroplasts is studied as a function of the levels of metabolites (3-phosphoglycerate, orthophosphate, hexose monophosphate, and ATP) as determined in whole chloroplasts of Spinacia oleracea in light and dark.     

A novel minisatellite at a cloned hamster telomere

The ends of eukaryotic chromosomes have special properties and roles in chromosome behavior. Selection for telomere function in yeast, using a Chinese hamster hybrid cell line as the source DNA, generated a stable yeast artificial chromosome clone containing 23 kb of DNA adjacent to (TTAGGG)n, the vertebrate telomeric repeat. The common repetitive element d(GT)n appeared to be responsible for most of the other stable clones. Circular derivatives of the TTAGGG-positive clone that could be propagated in E. coli were constructed. These derivatives identify a single pair of hamster telomeres by fluorescence in situ hybridization. The telomeric repeat tract consists of (TTAGGG)n repeats with minor variations, some of which can be cleaved with the restriction enzyme MnlI. Blot hybridization with genomic hamster DNA under stringent conditions confirms that the TTAGGG tracts are cleaved into small fragments due to the presence of this restriction enzyme site, in contrast to mouse telomeres. Additional blocks of (TTAGGG)n repeats are found 4–5 kb internally on the clone. The terminal region of the clone is dominated by a novel A-T rich 78 bp tandemly repeating sequence; the repeat monomer can be subdivided into halves distinguished by more or less adherence to the consensus sequence. The sequence in genomic DNA has the same tandem organization in probably a single primary locus of >20–30 kb and is thus termed a minisatellite.     

Pyruvate orthophosphate dikinase of c(3) seeds and leaves as compared to the enzyme from maize

Pyruvate orthophosphate dikinase (PPDK) was found in various immature seeds of C₃ plants (wheat, pea, green bean, plum, and castor bean), in some C₃ leaves (tobacco, spinach, sunflower, and wheat), and in C₄ (maize) kernels. The enzyme in the C₃ plants cross-reacts with rabbit antiserum against maize PPDK. Based on protein blot analysis, the apparent subunit size of PPDK from wheat seeds and leaves and from sunflower leaves is about 94 kdaltons, the same as that of the enzyme from maize, but is slightly less (about 90 kdaltons) for the enzyme from spinach and tobacco leaves. The amount of this enzyme per mg of soluble protein in C₃ seeds and leaves is much less than in C₄ leaves. PPDK is present in kernels of the C₄ plant, Zea mays in amounts comparable to those in C₄ leaves.

Regulatory properties of the enzyme from C₃ tissues (wheat) are similar to those of the enzyme from C₄ leaves with respect to in vivo light activation and dark inactivation (in leaves) and in vivo cold lability (seeds and leaves).

Following incorporation of ¹⁴CO₂ by illuminated wheat pericarp and adjoining tissue for a few seconds, the labeled metabolites were predominantly products resulting from carboxylation of phosphoenolpyruvate, with lesser labeling of compounds formed by carboxylation of ribulose 1,5-bisphosphate and operation of the reductive pentose phosphate cycle of photosynthesis. PPDK may be involved in mechanisms of amino acid interconversions during seed development.

     

Spinach pyruvate kinase isoforms : partial purification and regulatory properties

Pyruvate kinase from spinach (Spinacea oleracea L.) leaves consists of two isoforms, separable by blue agarose chromatography. Both isoforms share similar pH profiles and substrate and alternate nucleotide K_m values. In addition, both isoforms are inhibited by oxalate and ATP and activated by AMP. The isoforms differ in their response to three key metabolites; citrate, aspartate, and glutamate. The first isoform is similar to previously reported plant pyruvate kinases in its sensitivity to citrate inhibition. The K_i for this inhibition is 1.2 millimolar citrate. The second isoform is not affected by citrate but is regulated by aspartate and glutamate. Aspartate is an activator with a K_a of 0.05 millimolar, and glutamate is an inhibitor with a K_i of 0.68 millimolar. A pyruvate kinase with these properties has not been previously reported. Based on these considerations, we suggest that the activity of the first isoform is regulated by respiratory metabolism. The second isoform, in contrast, may be regulated by the demand for carbon skeletons for use in ammonia assimilation.     

Ion-retardation desalting of blood and other animal tissues for separation of soluble metabolites by two-dimensional chromatography

Metabolites present in acid extracts of mammalian tissues were desalted by passing the extracts through AG11A8 ion-retardation resin. Quantitative recoverles of alanine, aspartate, glucose, glutamate, glutamine, lactate, leucine, and maltose were 95, 100, 92, 85, 96, 90, 97, and 100%, respectively. Effective desalting allows metabolites present in tissue extracts to be separated by two-dimenslonal paper chromatography.     

Autophagy in development and stress responses of plants

The uptake and degradation of cytoplasmic material by vacuolar autophagy in plants has been studied extensively by electron microscopy and shown to be involved in developmental processes such as vacuole formation, deposition of seed storage proteins and senescence, and in the response of plants to nutrient starvation and to pathogens. The isolation of genes required for autophagy in yeast has allowed the identification of many of the corresponding Arabidopsis genes based on sequence similarity. Knockout mutations in some of these Arabidopsis genes have revealed physiological roles for autophagy in nutrient recycling during nitrogen deficiency and in senescence. Recently, markers for monitoring autophagy in whole plants have been developed, opening the way for future studies to decipher the mechanisms and pathways of autophagy, and the function of these pathways in plant development and stress responses.